COMPREHENSIVE UTILIZATION OF GEOTHERMAL AND SOLAR ENERGY TO EXPLOIT GAS HYDRATES BURIED IN OCEANIC SEDIMENTS

Ning, Fulong, Jiang, Guosheng, Zhang, Ling

07 1900

How to exploit and make use of natural gas hydrates in oceans will weigh much in the future researches. Unlike the oil or gas reservoirs, the distributions of natural gas hydrate are very complicated and don’t congregate massively in oceanic sediments. Besides, factors such as seafloor geohazards and climate must be taken into account, which makes it much more difficult and complicated to exploit oceanic gas hydrates than conventional oil or gas. Nowadays neither of such methods as thermal stimulation, depressurization, inhibitor injection, carbon dioxide replacement and mixing exploitation etc. is applied to exploit gas hydrates in marine sediments because of their disadvantages. This paper introduces a conception of combining solar and geothermal energy for gas hydrates exploitation. The model mainly includes five parts: solar energy transferring module, sea water circulating module, underground boiler module, platform and gas-liquid separating module. Solar cells and electric heaters are used to heat the formations containing hydrates. Because they become relatively more mature and cheaper, it’s the key of how to utilize the geothermy to exchange heat in developing this conception, which needs solution of fluid leakage, circulating passages and heat-exchange interface problems in building underground boiler. Probably it’s a feasible measure to use an effective hydraulic control system and hydraulic fracturing. The idea should be a good choice to exploit marine gas hydrates by combining solar and geothermal energy since this method has a great advantage either in terms of efficiency or cost.

marine gas hydrates

exploitation methods

geothermal energy

solar energy

underground boiler

International Conference on Gas Hydrates

ICGH

NEPTUNE-CANADA BASED GEOPHYSICAL IMAGING OF GAS HYDRATE IN THE BULLSEYE VENT

Willoughby, E.C., Mir, R, Scholl, Carsten, Edwards, R.N.

07 1900

Using the NEPTUNE-Canada cable-linked ocean-floor observatory we plan continuous, real-time monitoring of the gas hydrate-associated, “Bullseye” cold vent offshore Vancouver Island. Our group inferred the presence of a massive gas hydrate deposit there, based on the significant resistivity anomaly in our controlled-source electromagnetic (CSEM) dataset, as well as anomalously heightened shear moduli, from seafloor compliance data. This interpretation was confirmed by drilling by IODP expedition 311 (site U1328), which indicated a 40 m thick gas hydrate layer near the surface. Sporadic venting and variations in blanking in yearly single-channel seismic surveys suggest the system is evolving in time. We are preparing two stationary semi-permanent imaging experiments: a CSEM and a seafloor compliance installation. These are designed not only to assess the extent of the gas hydrate deposit, but also for long-term monitoring of the gas hydrate/free gas system. The principle of the CSEM experiment is to input a particular electromagnetic signal at a transmitter (TX) dipole on the seafloor, and to record the phase and amplitude of the response at several seafloor receiver (RX) dipoles, at various TX-RX separations. The data are sensitive to the underlying resistivity, which is increased when conductive pore water is displaced by electrically-insulating gas hydrate. The experiment is controlled onshore, and can be expanded to include a downhole TX. Repeated soundings at this site, over several years, will allow measurement of minute changes in resistivity as a function of depth, and by inference, changes in gas hydrate or underlying free gas distribution. Similarly, the displacement of pore fluids by solid gas hydrate will affect elastic parameters. Thus, seafloor compliance data, the transfer function between pressure and seafloor displacement time series, most sensitive to shear modulus as a function of depth, will be gathered continuously to monitor the evolution of the gas hydrate distribution.

marine gas hydrates

NEPTUNE

CSEM

seafloor compliance

ocean observatory

Bullseye Vent

cold vent

methane seep

electrical resistivity

remote sensing

shear modulus

ICGH

International Conference on Gas Hydrates

Temporal Variations in the Compliance of Gas Hydrate Formations

Roach, Lisa Aretha Nyala

20 March 2014

Seafloor compliance is a non-intrusive geophysical method sensitive to the shear modulus of the sediments below the seafloor. A compliance analysis requires the computation of the frequency dependent transfer function between the vertical stress, produced at the seafloor by the ultra low frequency passive source-infra-gravity waves, and the resulting displacement, related to velocity through the frequency. The displacement of the ocean floor is dependent on the elastic structure of the sediments and the compliance function is tuned to different depths, i.e., a change in the elastic parameters at a given depth is sensed by the compliance function at a particular frequency. In a gas hydrate system, the magnitude of the stiffness is a measure of the quantity of gas hydrates present. Gas hydrates contain immense stores of greenhouse gases making them relevant to climate change science, and represent an important potential alternative source of energy. Bullseye Vent is a gas hydrate system located in an area that has been intensively studied for over 2 decades and research results suggest that this system is evolving over time. A partnership with NEPTUNE Canada allowed for the investigation of this possible evolution. This thesis describes a compliance experiment configured for NEPTUNE Canada’s seafloor observatory and its failure. It also describes the use of 203 days of simultaneously logged pressure and velocity time-series data, measured by a Scripps differential pressure gauge, and a Güralp CMG-1T broadband seismometer on NEPTUNE Canada’s seismic station, respectively, to evaluate variations in sediment stiffness near Bullseye. The evaluation resulted in a (- 4.49 x10-3± 3.52 x 10-3) % change of the transfer function of 3rd October, 2010 and represents a 2.88% decrease in the stiffness of the sediments over the period. This thesis also outlines a new algorithm for calculating the static compliance of isotropic layered sediments.

SEAFLOOR COMPLIANCE

GAS HYDRATES

BULLSEYE VENT

TREND ANALYSIS

SENSITIVITY ANALYSIS

EIGENPARAMETER ANALYSIS

HYDRATE MASS VARIATION

LONG TERM TRENDS IN HYDRATE MASS

MODIFIED YORK METHOD

MARINE GEOPHYISCS

MARINE SEDIMENT

NEPTUNE CANADA

SHEAR MODULUS

GAS HYDRATE CONCENTRATIONS

CASCADIA MARGIN

MARINE GAS HYDRATES

INFRA-GRAVITY WAVES

SEISMOMETERS

SCRIPPS DIFFERENTIAL PRESSURE GAUGE

SCRIPPS DPG

ODP SITE 889

BROADBAND SEISMOMETER

gPhone

DGP calibration

Bottom Pressure Recorder

Guralp CGM-1T

Coherence

transfer function bounds

f-test

bootstrapping

wave propagation matrix

static solution

ocean bottom seismometer

tsunami

earthquakes

Modified York least squares

temporal variations

linear trend in gas hydrates

Power spectral densities

1D compliance solution

1D compliance algorithm

seafloor compliance instrumentation

Micro-g gravitimeter

triple phase boundary equation

ultra-low frequency seismics

seafloor pressure spectrum

seafloor gravity spectrum

pacific ocean

off-shore British Columbia

seafloor observatory

static compliance of layered structures

geophysics

gas hydrate characterization

0373

Temporal Variations in the Compliance of Gas Hydrate Formations

Roach, Lisa Aretha Nyala

20 March 2014

Seafloor compliance is a non-intrusive geophysical method sensitive to the shear modulus of the sediments below the seafloor. A compliance analysis requires the computation of the frequency dependent transfer function between the vertical stress, produced at the seafloor by the ultra low frequency passive source-infra-gravity waves, and the resulting displacement, related to velocity through the frequency. The displacement of the ocean floor is dependent on the elastic structure of the sediments and the compliance function is tuned to different depths, i.e., a change in the elastic parameters at a given depth is sensed by the compliance function at a particular frequency. In a gas hydrate system, the magnitude of the stiffness is a measure of the quantity of gas hydrates present. Gas hydrates contain immense stores of greenhouse gases making them relevant to climate change science, and represent an important potential alternative source of energy. Bullseye Vent is a gas hydrate system located in an area that has been intensively studied for over 2 decades and research results suggest that this system is evolving over time. A partnership with NEPTUNE Canada allowed for the investigation of this possible evolution. This thesis describes a compliance experiment configured for NEPTUNE Canada’s seafloor observatory and its failure. It also describes the use of 203 days of simultaneously logged pressure and velocity time-series data, measured by a Scripps differential pressure gauge, and a Güralp CMG-1T broadband seismometer on NEPTUNE Canada’s seismic station, respectively, to evaluate variations in sediment stiffness near Bullseye. The evaluation resulted in a (- 4.49 x10-3± 3.52 x 10-3) % change of the transfer function of 3rd October, 2010 and represents a 2.88% decrease in the stiffness of the sediments over the period. This thesis also outlines a new algorithm for calculating the static compliance of isotropic layered sediments.

SEAFLOOR COMPLIANCE

GAS HYDRATES

BULLSEYE VENT

TREND ANALYSIS

SENSITIVITY ANALYSIS

EIGENPARAMETER ANALYSIS

HYDRATE MASS VARIATION

LONG TERM TRENDS IN HYDRATE MASS

MODIFIED YORK METHOD

MARINE GEOPHYISCS

MARINE SEDIMENT

NEPTUNE CANADA

SHEAR MODULUS

GAS HYDRATE CONCENTRATIONS

CASCADIA MARGIN

MARINE GAS HYDRATES

INFRA-GRAVITY WAVES

SEISMOMETERS

SCRIPPS DIFFERENTIAL PRESSURE GAUGE

SCRIPPS DPG

ODP SITE 889

BROADBAND SEISMOMETER

gPhone

DGP calibration

Bottom Pressure Recorder

Guralp CGM-1T

Coherence

transfer function bounds

f-test

bootstrapping

wave propagation matrix

static solution

ocean bottom seismometer

tsunami

earthquakes

Modified York least squares

temporal variations

linear trend in gas hydrates

Power spectral densities

1D compliance solution

1D compliance algorithm

seafloor compliance instrumentation

Micro-g gravitimeter

triple phase boundary equation

ultra-low frequency seismics

seafloor pressure spectrum

seafloor gravity spectrum

pacific ocean

off-shore British Columbia

seafloor observatory

static compliance of layered structures

geophysics

gas hydrate characterization

0373